Stability examination of non-linear convection flow with partial slip phenomenon in a Riga plate channel

被引:0
作者
Kumar, Rakesh [1 ]
Sharma, Tanya [1 ]
机构
[1] Cent Univ Himachal Pradesh, Srinivasa Ramanujan Dept Math, Shahpur Campus, Shahpur 176206, India
关键词
non-linear convection; partial slip flow; Riga channel flow; hybrid nanofluid; linear stability analysis; HEAT-TRANSFER; NANOFLUID;
D O I
10.1088/1873-7005/ad73ff
中图分类号
O3 [力学];
学科分类号
08 ; 0801 ;
摘要
The present work examines the linear stability of non-linear convected flow inside a Riga plate channel. The channel is filled with hybrid nanoliquid and is under the novel influence of the partial slip phenomenon in the present scenario. The left domain of the channel is supported by the Riga sheet whereas the right part is bounded by a sheet of slippery nature. The stability model for this partial slip mechanism is developed in the form of an eigenvalue problem which is explored via the Chebyshev pseudospectral method in combination with the QZ-algorithm. It is reported that the convection forces in hybrid nanofluid are amplified with Riga magnetic number (Hr) under slip/no-slip assumptions. It is interestingly noted that the flow is destabilized by 11.47 % with non-linear convection (Nc) when considering no-slip at the right-hand sheet. However, the stability region is enlarged with Nc by 9.53 % in the presence of slip at the right-hand sheet. The partial-slip (gamma) assumption in the channel decelerates the growth rate of disturbances. The increment in Fe3O4-nanoparticles over the fixed volume of CoFe2O4-nanoparticles hampers the instability of the hybrid nanofluid mixture.
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页数:21
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